Synchronous measurement system

ABSTRACT

A synchronous measurement system includes a controller and a sensor unit connected to the controller. The controller transmits a plurality of synchronization commands to the sensor unit at every predetermined interval. The sensor unit transmits measurement data to the controller in synchronization with each one of the plurality of synchronization commands. The controller includes a data processing section configured to process the measurement data transmitted from the sensor unit and a counter configured to count the synchronization command. The controller builds a data structure in which a count value of the synchronization command corresponding to the measurement data is added to the measurement data.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a U.S. National Phase Application under 35 U.S.C.371 of International Application No. PCT/JP2014/001272, filed on Mar. 7,2014. This application claims priority to Japanese Patent ApplicationNo. 2013-053257, filed Mar. 15, 2013. The entire disclosures of theabove applications are expressly incorporated by reference herein.

TECHNICAL FIELD

The present invention relates to a synchronous measurement system andthe like.

BACKGROUND ART

A plurality of sensor units are sometimes mounted on an object to bedetected to measure various kinds of information such as the movement,the posture, and the distortion of the object to be detected. In thiscase, data collected from the respective plurality of sensor units needto be synchronized with one another.

In JP-A-2004-80132, for example, for synchronous detection ofcommunication, a master communication circuit and a plurality of slavecommunication circuits are prepared. When the master communicationcircuit communicates with one of the plurality of slave communicationcircuits, the master communication circuit updates count data for thestart of synchronization and synchronous detection in such a manner as0, 1, 2, . . . and transmits the count data in addition to communicationdata. Each of the plurality of slave communication circuits can obtainsynchronization timing of communication by receiving the count data.

In Japanese Patent No. 4926752, a sensor terminal, which receives ameasurement start command from a server, incorporates a clock section.The sensor terminal side obtains time of measurement start from theclock section and records the time in measurement data.

TECHNICAL PROBLEM

In JP-A-2004-80132, communication between the master communicationcircuit and the slave communication circuit is synchronized. Theplurality of sensor units are not simultaneously synchronized. InJP-A-2004-80132, in order to synchronize communication, when the mastercommunication circuit communicates with one of the plurality of slavecommunication circuits, the master communication circuit needs totransmit the count data for the start of synchronization and synchronousdetection in addition to the communication data. Therefore, since anamount of information to be transmitted is large, JP-A-2004-80132 cannotbe applied to synchronous measurement.

The synchronous detection system of JP-A-2004-80132 can be referred toas centralized type. This is because synchronization of communication issolely managed by the master communication circuit in a centralizedmanner according to the transmission of the count data from the mastercommunication circuit. In the centralized type, the master communicationcircuit is always involved in synchronous detection. Therefore, timeoccupied by the synchronous detection is long in the mastercommunication circuit and time for displaying an original function ofthe master communication circuit is reduced.

In Japanese Patent No. 4926752, the sensor terminal needs to recordmeasurement time. Therefore, Japanese Patent No. 4926752 is unsuitablefor, in particular, synchronous measurement in which a samplingfrequency is high. When clock sections are respectively mounted on alarge number of installed sensor terminals, costs increase.

SUMMARY OF THE INVENTION

An object of some aspects of the invention is to provide a synchronousmeasurement system that can manage, on a controller side,synchronization timing of measurement data transmitted from a sensorunit to the controller on the basis of an instruction for asynchronization start output from the controller.

(1) An aspect of the invention relates to a synchronous measurementsystem including: a controller; and a sensor unit connected to thecontroller. The controller transmits a synchronization command to thesensor unit. The sensor unit transmits measurement data to thecontroller according to the synchronization command. The controllerincludes: a data processing section configured to process themeasurement data transmitted from the sensor unit; and a counterconfigured to count the synchronization command. The controller builds adata structure to which the measurement data and a count value of thesynchronization command corresponding to the measurement data are added.

In the aspect of the invention, the controller builds the data structurein which the count value of the synchronization command is added to themeasurement data output from the sensor unit for each of synchronizationcommands. Therefore, the controller side can manage synchronizationtiming of the measurement data. Consequently, a lack and redundancy ofdata are easily known from count values of the synchronization commands.Therefore, as a precondition in synchronizing measurement data outputfrom one sensor unit and measurement data output from another sensorunit, it is guaranteed that the same count value is added to themeasurement data to be synchronized output from the sensor units.

(2) The aspect of the invention may be configured such that an ID forspecifying the sensor unit is added to the data structure.

Then, measurement data from a plurality of sensor units input to onecontroller are distinguished by IDs. Moreover, a plurality ofmeasurement data having the same count value are synchronized with oneanother.

(3) The aspect of the invention may be configured such that a pluralityof the controllers are provided, and the controller transmit thesynchronization commands to the sensor unit. In this case, as in thecase explained above, a plurality of measurement data having the samecount value are synchronized with one another.

(4) The aspect of the invention may be configured such that, when thecount value is missing, the controller adds a data structurecorresponding to the missing count value. Then, even if measurement datais missing because of some reason, it is possible to build a datastructure to correspond to all count values. Therefore, by rearrangingdata in the order of the count values of the synchronization commands,data synchronized among the sensor units are easily compared.

(5) The aspect of the invention may be configured such that the addeddata structure is error data. According to the error data, it ispossible to immediately recognize that measurement data is not obtainedat timing corresponding to the count value of the error data. Thesignificance of supplementing the missing data with the error data inthis way resides in preventing a synchronization shift due to a missingcount value rather than securing continuity of the data itself.

(6) The aspect of the invention may be configured such that the addeddata structure is interpolated on the basis of data corresponding tocount values before and after the missing count value. The significanceof supplementing the missing data with the interpolation data in thisway resides in preventing a synchronization shift due to the missingcount value and securing continuity of the data itself.

(7) The aspect of the invention may be configured such that, when aplurality of data structures having the same count value are present,one data structure of the plurality of data structures is left and theother data structure is deleted. Consequently, it is possible to preventa synchronization shift due to redundancy of data.

(8) The aspect of the invention may be configured such that thecontroller includes a main controller and a sub-controller connected tothe main controller, the sensor unit being connected to thesub-controller, and in the sub-controller, the data processing sectionand the counter are provided. In this way, the controller to which thesensor unit is connected can be provided as the sub-controller. Ahigh-order main controller that manages the sub-controller can beprovided.

(9) The aspect of the invention may be configured such that thecontroller includes a main controller and a sub-controller connected tothe main controller, the sensor unit being connected to thesub-controller, the data processing section includes a first dataprocessing section provided in the main controller and a second dataprocessing section provided in the sub-controller, one of the first dataprocessing section and the second data processing section performsprocessing of a data structure having an abnormal count value, and theother performs processing for adding the count value of the counter tothe measurement data.

In this way, roles of the data processing for the data structure can beshared by the main controller and the sub-controller. In particular,processing for a data structure having a missing count value or the samecount value can be performed off-line. Therefore, the main controllercan perform off-line processing in an idle time.

(10) The aspect of the invention may be configured such that thesub-controller includes a sub-controller master and a sub-controllerslave connected to the sub-controller master, the main controllertransmits a start command to the sub-controller master, thesub-controller master generates a trigger signal according to receptionof the start command and transmits the trigger signal to thesub-controller slave, and the sub-controller master and thesub-controller slave transmit the synchronization command to the sensorunit on the basis of the trigger signal.

The sub-controller master, which receives the start command from themain controller, generates the trigger signal and transmits the triggersignal to the sub-controller slave. Each of a plurality of thesub-controllers (the sub-controller master and the sub-controller slave)transmits the synchronization command to a plurality of the sensor unitson the basis of the trigger signal. Consequently, it is possible tosimultaneously synchronize all the sensor units connected to all thesub-controller. Moreover, the main controller is not involved insynchronous detection after transmitting the start command. Each of theplurality of sub-controllers can perform the synchronous detection in adistributed manner.

(11) The aspect of the invention may be configured such that the sensorunit includes at least one of an acceleration sensor and an angularvelocity sensor. Consequently, it is possible to measure various kindsof information such as the movements, the postures, and the distortionsin a plurality of places of an object to be detected (a human body, amoving object, an immobile property, etc.) in synchronization.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing a synchronous measurement systemaccording to an embodiment of the invention.

FIG. 2 is a block diagram showing a main controller shown in FIG. 1.

FIG. 3 is a block diagram showing a configuration common to a pluralityof sub-controllers shown in FIG. 1.

FIG. 4 is a block diagram of a sensor unit shown in FIG. 1.

FIG. 5 is a timing chart showing a synchronous measurement operation.

FIG. 6A is a diagram showing data structures stored in memories of thesensor unit.

FIG. 6B is a diagram showing data structures stored in memories of thesub-controller.

FIG. 6C is a diagram showing data structures stored in memories of themain controller.

FIG. 7 is a data structure having a skipped number in count values.

FIG. 8 is a diagram showing a data sequence in which the skipped numberis eliminated by addition of error data.

FIG. 9 is a diagram showing a data sequence in which the skipped numberis eliminated by interpolation based on data before and after theskipped number.

FIG. 10 is a diagram showing a data sequence in which there isredundancy in count values.

FIG. 11 is a diagram showing a data sequence in which the redundancy ofthe count values is eliminated by deletion.

FIG. 12 is a diagram showing an error indication example in an operationcheck mode.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

A preferred embodiment of the invention is explained in detail below.Note that the embodiment explained below does not unduly limit contentsof the invention described in the appended claims. All of componentsexplained in the embodiment are not always essential as means forsolution of the invention.

1. Synchronous measurement system FIG. 1 shows a synchronous measurementsystem 1 according to this embodiment. In FIG. 1, the synchronousmeasurement system 1 includes, as at least one controller, a maincontroller 10 and a plurality of sub-controllers 20A to 20ELAN-connected to the main controller 10. A plurality of sensor units 30are connected to each of the plurality of sub-controllers 20A to 20E.

The main controller 10 is, for example, a personal computer and includesa main body 11, a display section 12, a keyboard 13, and an Ethernet hub14. The main controller 10 is installed with a synchronous measurementsystem execution program and controls synchronous measurement in thefive sub-controllers 20A to 20E.

The plurality of sub-controllers 20A to 20E are connected to theEthernet hub 14 of the main controller 10 by Ethernet cables 15. One ofthe plurality of sub-controllers 20A to 20E is a sub-controller master20A.

The other four sub-controllers are sub-controller slaves 20B to 20Econnected to the sub-controller master 20A.

In this embodiment, the plurality of sub-controllers 20A to 20E aredaisy chain-connected by, for example, optical communication cables 21.That is, the sub-controller slave 20B is connected to the sub-controllermaster 20A, the sub-controller slave 20C is connected to thesub-controller slave 20B, and the other sub-controller slaves areconnected in series. Then, even if the number of sub-controller slavesincreases, the sub-controller master and the plurality of sub-controllerslaves only have to be connected in series. Cable laying and the likeare easy compared with star type connection.

Each of the plurality of sub-controllers 20A to 20E includes a pluralityof bus ports, for example, CAN (Controller Area Network) bus ports 22.Note that the CAN is a highly reliable communication form robust againstan error and noise and is suitable for this embodiment in that abroadcasting command can be used. However, the bus ports may adopt otherbus specifications and are not limited to the CAN. Maximum six sensorunits are connected to the CAN bus cable 23 connected to each of the CANbus ports 22. Since eight CAN bus ports 22 are provided in each of theplurality of sub-controllers 20A to 20E, maximum forty-eight sensorunits can be connected to each of the plurality of sub-controllers 20Ato 20E. In this embodiment, twelve sensor units 30 are connected to thesub-controller master 20A and forty-eight sensor units 30 are connectedto each of the sub-controller slaves 20B to 20E. The entire system 1includes two hundred and four sensor units 30.

FIG. 2 is a block diagram showing the main controller 10. In FIG. 2,besides the display section 12 and the keyboard 13, a command generatingsection 102, a command decoder 103, a data processing section 104, amemory 105, a clocking section 106, a communication section 107, and thelike are connected to a bus line of a CPU 101 provided in the main body11 shown in FIG. 1. The Ethernet hub 14 shown in FIG. 1 is connected tothe communication section 107. For example, when data from the sensorunits 30 are collected, the command generating section 102 generates adata collection start command (hereinafter, start command). In anoperation check mode before data measurement, the command generatingsection 102 generates, for example, a reset command as a check command.The command decoder 103 decodes end commands and the like transmittedfrom the sub-controllers 20A to 20E. The data processing section 104 isexplained below.

FIG. 3 is a block diagram showing a configuration common to theplurality of sub-controllers 20A to 20E. A command generating section202, a command decoder 203, a data processing section 204, a memory 205,a trigger transmitting section 206, a trigger receiving section 207, acounter 208, a first communication section 209, and a secondcommunication section 210 are connected to a bus line of a CPU 201provided in each of the sub-controllers 20A to 20E. The Ethernet cables15 shown in FIG. 1 are connected to ports of the first communicationsection 209. The CAN ports 22 shown in FIG. 1 are connected to thesecond communication section 210.

A light emitting section 211 is connected to the trigger transmittingsection 206. A light receiving section 212 is connected to the triggerreceiving section 207. The optical communication cable 21 is connectedto the light emitting section 211 or the light receiving section 212,whereby a trigger signal, which is an optical signal, can be emitted orreceived. In the sub-controller master 20A, the optical communicationcable 21 is connected to only the light emitting section 211. In thesub-controller slave 20E, the optical communication cable 21 isconnected to only the light receiving section 212. Each of thesub-controllers 20A to 20E includes an optical switch 213 configured todivide the trigger signal received by the light receiving section 212and input the trigger signal to the light emitting section 211. In eachof the sub-controller slaves 20B to 20D, the optical switch 213 isturned on and the optical communication cable 21 is connected to both ofthe light emitting section 211 and the light receiving section 212.Consequently, each of the sub-controller slaves 20B to 20D can transferthe trigger signal from an upstream side to a downstream side. When thetrigger signal is transferred, after the optical signal (the triggersignal) from the upstream side is received by the light receivingsection 212 and converted into an electric signal, light is emittedagain by the light emitting section 211. Therefore, the optical signalis waveform-shaped. When the trigger signal is transmitted as a digitalelectric signal, the trigger signal can be waveform-shaped by providinga buffer in the sub-controller slave. Consequently, synchronizationaccuracy is improved. As in the sub-controller slaves 20B to 20D, in thesub-controller master 20A, the switch 213 is turned on and the triggersignal output from the trigger transmitting section 206 is input to thetrigger receiving section 207.

FIG. 4 shows a block diagram of the sensor unit 30. The sensor unit 30is attached to an analysis target object and performs processing fordetecting a given physical quantity. In this embodiment, as shown inFIG. 4, a sensor includes at least one, for example, a plurality ofsensors 301 x to 301 z and 302 x to 302 z.

The sensor in this embodiment is a sensor configured to detect the givenphysical quantity and output a signal (data) corresponding to themagnitude of the detected physical quantity (e.g., acceleration, angularvelocity, velocity, or angular acceleration). In this embodiment, thesensor includes a six-axis motion sensor including three-axisacceleration sensors 301 x to 301 z (an example of inertial sensors)configured to detect accelerations in X-axis, Y-axis, and Z-axisdirections and three-axis gyro sensors (an example of angular velocitysensors and inertial sensors) 302 x to 302 z configured to detectangular velocities in the X-axis, Y-axis, and Z-axis directions.

The sensor unit 30 can include, on a bus line of a CPU 303, a commandgenerating section 304, a command decoder 305, a data processing section306, and a communication section 307. The command decoder 305 decodes asynchronization command and a check command such as a reset command. Thedata processing section 306 processes measurement data of the sensors301 x to 301 z and 302 x to 302 z into a data structure associated withan ID of the sensor unit 30 and outputs the data structure from thecommunication section 307. In this embodiment, 1 to 6 are allocated toIDs of the sensor units 30 connected to odd number-th CAN ports 22. 7 to12 are allocated to IDs of the sensor units 30 connected to evennumber-th CAN ports 22. However, the IDs are not limited to this. Forexample, different IDs may be given to all of the forty-eight sensorunits 30. The data processing section 306 may perform processing forbias correction and temperature correction of the sensors 301 x to 301 zand 302 x to 302 z. Note that functions for the bias correction and thetemperature correction may be incorporated in the sensor itself.

2. Synchronous measurement operation The operation in the synchronousmeasurement system 1 configured as explained above is explained.Measurement is started by operating the keyboard 13 of the maincontroller 10 shown in FIG. 1. The main controller 10 generates a startcommand in the command generating section 102. In the start command, thenumber of times of measurement N can be designated. The start command istransmitted to all the sub-controllers 20A to 20E via the communicationsection 107, the Ethernet hub 14, and the Ethernet cables (FIG. 1) shownin FIG. 2. Accuracy of synchronization is not required in transmissionof the start command from the main controller 10 to the plurality ofsub-controllers 20A to 20E.

Each of the sub-controllers 20A to 20E receives the start command in thefirst communication section 209 shown in FIG. 3 and decodes the startcommand in the command decoder 203. As shown in FIG. 5, thesub-controller master 20A generates, for example, a trigger signal,which is a digital signal, in the trigger transmitting section 206according to the reception of the start command and outputs the triggersignal as an optical signal in the light-emitting section 211.

Since the switch 213 shown in FIG. 3 is on, the trigger signaltransmitted by the trigger transmitting section 206 is input to thetrigger receiving section 207 via the switch 213. The sub-controllermaster 20A receives, a trigger signal A (see FIG. 5).

On the other hand, each of the sub-controller slaves 20B to 20E receivesthe start command from the main controller 10 via the firstcommunication section 209 and decodes the start command in the commanddecoder 203. Consequently, each of the sub-controller slaves 20B to 20Ecan be set in a standby state for staying on standby for reception of atrigger signal.

Thereafter, each of the sub-controller slaves 20B to 20E receives, inthe light receiving section 212, the trigger signal from thesub-controller master 20A directly or via the sub-controller slaves onthe upstream side and receives a trigger signal B to a trigger signal Ein the trigger receiving section 207 (see FIG. 5). In this embodiment, adigital signal is transmitted by optical communication as the triggersignal. As shown in FIG. 5, synchronization timing can be taken by anedge of the trigger signal. Therefore, time deviation T1 from theissuance of the start command to the reception of the trigger signal Ato the trigger signal E shown in FIG. 5 is in the order of several nSand can be neglected.

When the trigger signal is received in the trigger receiving section207, each of the sub-controllers 20A to 20E generates a synchronizationcommand in the command generating section 202 shown in FIG. 3 on thebasis of the edge of the trigger signal. Each of the sub-controllers 20Ato 20E transmits the synchronization command to the plurality of sensorunits 30 from the second communication section 210 via the CAN ports 22by broadcasting.

Each of the plurality of sensor units 30 connected to each of thesub-controllers 20A to 20E decodes, in the command decoder 305,synchronization commands A to E transmitted from the sub-controllers 20Ato 20E (see FIG. 5). Time deviation T2 of the synchronization commands Ato E shown in FIG. 5 is naturally larger than the time deviation T1 ofthe trigger signal A to the trigger signal E but is in the order ofseveral microseconds and can be neglected.

The sensors 301 x to 301 z and 302 x to 302 z of the sensor unit 30measure measurement data. The data processing section 306 outputs onlydata synchronizing with the synchronization command from thecommunication section 307 as a data structure of a predetermined format.However, the sensor unit 30 may start measurement and output themeasurement data in synchronization with the synchronization command. Inthis embodiment, first data after the input of the synchronizationcommand is output. The sub-controller 20A outputs first data after theinput of the synchronization command A as data 1. Similarly, forexample, the sub-controller 20E outputs first data after the input ofthe synchronization command E as the data 1. Note that, in thisembodiment, each of the sensor units 30 is performing high-speedsampling. A sampling frequency of the sensor unit 30 is, for example, 1KHz. In this case, if T2 is equal to or smaller than 1 mS, asynchronization shift does not occur. In this embodiment, since T2 is inthe order of microseconds, synchronous measurement is possible.

As explained above, the start command can include information the numberof times of measurement N. When N is 2 or more, the sub-controller 20Arepeatedly generates N trigger signals at every designated measurementinterval (see FIG. 5). The sensor unit 30 outputs the measurement data 1to N to the sub-controller 20A on the basis of each of the N triggersignals.

FIG. 6A shows a data structure 320 built by the data processing section306 of the sensor unit 30. The data structure 320 is configured by an IDof the sensor unit and six-axis data. The data processing section 306adds the ID of the sensor unit 30 to data output from the sensors 301 xto 301 z and 302 x to 302 z.

FIG. 6B shows a data structure 220 built by the data processing section204 of each of the sub-controllers 20A and 20B and stored in the memory205. In the data structure 220, as shown in FIG. 6B, a number of the CANport 22 and a count value of the synchronization command in the counter208 are added to the data structure 320 output from the sensor unit 30shown in FIG. 6A. Since the data is input to each of the sub-controllers20A and 20B via the CAN port 22, according to the number of the CAN port22 and an ID of the sensor unit 30 for each of the CAN ports 22, thesub-controller specifies which of the maximum forty-eight sensor units30 the sensor unit is. The counter 208 shown in FIG. 3 is counted upevery time the number of times N is set by the start command and, forexample, the synchronization command is issued. By recording a countvalue of the counter 208, it is specified which of the synchronizationcommands shown in FIG. 5 the data follows.

When data corresponding to the Nth synchronization command is input toeach of the sub-controllers 20A to 20E, the sub-controller issues, forexample, an end command by the command decoder 203 and inputs the endcommand to the main controller 10. When the main controller 10 issues,for example, a data collection command, each of the sub-controllers 20Ato 20E outputs the data stored in the memory 205 to the main controller10.

FIG. 6C shows a data structure 120 built by the data processing section104 of the main controller 10 and stored in the memory 105. In the datastructure 120, as shown in FIG. 6C, a sub-controller ID is added to thedata structure 220 output from each of the sub-controllers 20A to 20Eshown in FIG. 6B. According to the data structure 120 shown in FIG. 6C,it is specified when the data is output from which of the two hundredand four sensor units 30 in total. The sensor ID, the CAN port number,and the sub-controller ID shown in FIG. 6A to FIG. 6C are IDs forspecifying the two hundred and four sensor units 30 in total and are notlimited to hierarchically given IDs. For example, different sensor IDsmay be given to the two hundred and four sensor units in total. Then,the CAN port number and the sub-controller ID are unnecessary.

In order to adjust the data structure shown in FIG. 6C to resolutionduring an output, the data processing section 104 of the main controller10 can multiply a numerical value of the six-axis data shown in FIG. 6Cwith a coefficient or calculate time corresponding to the count value inthe counter 208 shown in FIG. 3 from the clocking section 106 shown inFIG. 2 and add the time to the data structure shown in FIG. 6C.

3. Data processing for eliminating a skipped number or redundancy of acount value FIGS. 7 to 11 show data sequences for explaining processingcarried out by the data processing section (also referred to as firstdata processing section) 104 of the main controller 10 or the dataprocessing section (also referred to as second data processing section)204 arranged in each of the plurality of sub-controllers 20A to 20E. Thedata sequences shown in FIGS. 7 to 11 are six-axis data measured bycertain one sensor unit 30. Sampling count values of the counter 208shown in FIG. 3 are added to the six-axis data. The data sequences shownin FIGS. 7 to 11 are sorted by the sampling count values and arrayed.

A skipped number (a missing count value) is present in the data sequenceshown in FIG. 7. Data corresponding to a sampling count value “10” ismissing. That is, for example, although the command generating section202 of the sub-controller 20A issues a tenth synchronization command andtransmits the synchronization command to the sensor unit 30, measurementdata corresponding to the synchronization command is not transmittedfrom the sensor unit 30 to the sub-controller 20A.

When the sampling count value in the data sequence is the skipped numberas shown in FIG. 7, the data processing section 104 or the dataprocessing section 204 can add a data structure corresponding to theskipped number as shown in FIG. 8 or 9. Then, even if measurement datais missing because of some reason, it is possible to build a datastructure to correspond to all count values. Therefore, by rearrangingdata in the order of the count values of the synchronization commands,data synchronized among the sensor units 30 are easily compared.

As shown in FIG. 8, data added as a count value “10” can be error data.The error data means data in a range in which the data is effective asmeasurement data. According to the addition of the error data, it ispossible to immediately recognize that measurement data is not obtainedat timing corresponding to the count value. The significance ofsupplementing the missing data with the error data in this way residesin preventing a synchronization shift due to a skipped number ratherthan securing continuity of the data itself.

Alternatively, as shown in FIG. 9, the data added as the count value“10” can be interpolated, for example, linearly interpolated on thebasis of data corresponding to count values “9” and “11” before andafter the skipped number. The significance of supplementing the missingdata with the interpolation data in this way resides in preventing asynchronization shift due to the skipped number and securing continuityof the data itself.

FIG. 10 shows an example in which a plurality of data having the samecount value “10” are present. That is, for example, after the commandgenerating section 202 of the sub-controller 20A issues a tenthsynchronization command and transmits the synchronization command to thesensor unit 30 and before the command generating section 202 issues aneleventh synchronization command, measurement data is transmitted fromthe sensor unit 30 to the sub-controller 20A twice.

When data corresponding to a sampling count value “10” in a datasequence is redundantly present as shown in FIG. 10, the data processingsection 104 or the data processing section 204 can leave one of two datacorresponding to the sampling count value “10” and delete the otherdata. Consequently, it is possible to prevent a synchronization shiftdue to the redundancy of the data.

The data processing shown in FIG. 8, 9, or 11 may be carried out in thedata processing section (the second data processing section) 204provided in each of the sub-controllers 20A to 20E or may be carried outin the data processing section (the first data processing section) 104of the main controller 10. In particular, processing for a datastructure having a missing count value (a skipped number) or the samecount value can be performed off-line. Therefore, the main controller 10can perform off-line processing in an idle time. Consequently, it ispossible to reduce a load on the sub-controllers 20A to 20E.

4. Error processing in the operation check mode or the like Thesynchronous measurement system 1 in this embodiment can carry out theoperation check mode before data measurement. The main controller 10transmits an operation check command to the sub-controllers 20A to 20E.Each of the sub-controllers 20A to 20E transmits, for example, a resetcommand to all the sensor units 30. The sensor unit 30 transmits an IDin response to the reset command from each of the sub-controllers 20A to20E.

Consequently, error information of the sensor unit 30 not responding tothe reset command can be displayed on the display section 12 by the maincontroller 10.

FIG. 12 shows an example of an error indication of the sensor unit 30.In FIG. 12, to correspond to each of the five sub-controllers 20A to20E, display regions are provided by the number of the sensor units 30connected to the sub-controller. A white indication indicates a normalsensor unit 30 and a black indication indicates the sensor unit 30 inwhich an error occurs. In the example shown in FIG. 12, an error isindicated in the sensor unit 30 of ID1 connected to the second CAN port22 of the sub-controller 20C. The error is considered to be caused by aconnection failure of the sensor unit 30 alone. Further, in FIG. 12, anerror is indicated in the sensor units 30 of ID1 to ID6 connected to thefifth CAN port 22 of the sub-controller 20D. The error is considered tobe caused by a connection failure of the CAN bus cable 23 to the fifthCAN port 22.

As explained above, a connection state of the main controller 10, theplurality of sub-controllers 20A to 20E, and the plurality of sensorunits 30, which is a precondition in performing synchronous measurement,can be checked and displayed on the display section 12 by the maincontroller 10. Therefore, an operator can shift to data measurementafter correcting a connection failure.

In this embodiment, when an error occurs during measurement, processingis continued as much as possible and measurement data is stored in themain controller 10. For example, when the number of times of a datareception failure in which, for example, each of the sub-controllers 20Ato 20E cannot receive data from the sensor unit 30 is equal to or largerthan a fixed number, the sub-controller notifies the main controller 10of an error only once and continues the processing. When each of thesub-controllers 20A to 20E detects that data cannot be received from acertain sensor unit 30, concerning the sensor unit 30, thesub-controller notifies the main controller 10 of an error only in thefirst detection and continues the processing.

When each of the sub-controllers 20A to 20E detects that data cannot bereceived from a certain CAN port 22, concerning the CAN port 22, thesub-controller notifies the main controller 10 of an error only in thefirst detection and continues the processing. When any one of thesub-controllers 20A to 20E cannot receive a trigger signal for a fixedtime, the sub-controller notifies the main controller 10 of an erroronly once. When the main controller 10 receives the error notification,the main controller 10 can forcibly stop the measurement processing ofthe sub-controller in which the error occurs.

When an error occurs in reading measurement data from any one of thesub-controllers 20A to 20E after the end of the measurement, the maincontroller 10 notifies the operator of an error together with asub-controller name and reads data from the sub-controller from whichthe data can be normally read. The main controller 10 stores measurementdata in the nonvolatile memory 205 in each of the sub-controllers 20A to20E until the start of the next measurement.

The embodiment is explained in detail above. However, those skilled inthe art could easily understand that various modifications are possiblewithout substantively departing from the new matters and the effects ofthe invention. Therefore, all such modifications are regarded as beingincluded in the scope of the invention. For example, the terms describedat least once together with broader or synonymous different terms in thespecification or the drawings can be replaced with the different terms.The configurations and the operations of the main controller, thesub-controller, the sub-controller master, the sub-controller slave, thesensor unit, and the like are not limited to those explained in theembodiment. Various modifications of the configurations and theoperations are possible. For example, the wired connection in theembodiment can be replaced with wireless connection.

1. A synchronous measurement system comprising: a controller; and asensor unit connected to the controller, wherein the controllertransmits a synchronization command to the sensor unit, the sensor unittransmits measurement data to the controller according to thesynchronization command, the controller includes: a data processingsection configured to process the measurement data transmitted from thesensor unit; and a counter configured to count the synchronizationcommand, and the controller builds a data structure to which themeasurement data and a count value of the synchronization commandcorresponding to the measurement data are added.
 2. The synchronousmeasurement system according to claim 1, wherein an ID for specifyingthe sensor unit is added to the data structure.
 3. The synchronousmeasurement system according to claim 1, wherein a plurality of thecontrollers are provided and the controller transmit the synchronizationcommands to the sensor unit.
 4. The synchronous measurement systemaccording to claim 1, wherein, when the count value is missing, thecontroller adds a data structure corresponding to the missing countvalue.
 5. The synchronous measurement system according to claim 4,wherein the added data structure is error data.
 6. The synchronousmeasurement system according to claim 4, wherein the added datastructure is interpolated on the basis of data corresponding to countvalues before and after the missing count value.
 7. The synchronousmeasurement system according to claim 1, wherein, when a plurality ofdata structures having a same count value are present, one datastructure of the plurality of data structures is left and the other datastructure is deleted by the controller.
 8. The synchronous measurementsystem according to claim 1, wherein the controller includes a maincontroller and a sub-controller connected to the main controller, thesensor unit being connected to the sub-controller, and in thesub-controller, the data processing section and the counter areprovided.
 9. The synchronous measurement system according to claim 1,wherein the controller includes a main controller and a sub-controllerconnected to the main controller, the sensor unit being connected to thesub-controller, the data processing section includes a first dataprocessing section provided in the main controller and a second dataprocessing section provided in the sub-controller and one of the firstdata processing section and the second data processing section performsprocessing of a data structure having an abnormal count value and theother performs processing for adding the count value of the counter tothe measurement data.
 10. The synchronous measurement system accordingto claim 8, wherein the sub-controller includes a sub-controller masterand a sub-controller slave connected to the sub-controller master, themain controller transmits a start command to the sub-controller master,the sub-controller master generates a trigger signal according toreception of the start command and transmits the trigger signal to thesub-controller slave, and the sub-controller master and thesub-controller slave transmit the synchronization command to the sensorunit on the basis of the trigger signal.
 11. The synchronous measurementsystem according to claim 1, wherein the sensor unit includes at leastone of an acceleration sensor and an angular velocity sensor. 12.(canceled)
 13. The synchronous measurement system according to claim 9,wherein the sub-controller includes a sub-controller master and asub-controller slave connected to the sub-controller master, the maincontroller transmits a start command to the sub-controller master, thesub-controller master generates a trigger signal according to receptionof the start command and transmits the trigger signal to thesub-controller slave, and the sub-controller master and thesub-controller slave transmit the synchronization command to the sensorunit on the basis of the trigger signal.